KR102081428B1 - Lighting apparatus for mounting on wall of tunnel and lens unit thereof - Google Patents

Abstract

The present invention relates to a wall-mount type lighting apparatus for a tunnel, to suppress dazzle of a driver. According to the present invention, the wall-mount type lighting apparatus for a tunnel comprises: a substrate made of a metallic material; a plurality of light sources installed on the substrate, wherein the substrate is mounted on a fixture to be mechanically tilted within a range of 10 to 20° and includes a plurality of surface-mounted device (SMD) LED packages or a plurality of chip on board (COB) LEDs; an illumination controller for each section of the tunnel including a dimmer for performing PWM control of the LED package through a wire or wirelessly, a control unit for controlling the dimmer, and a communication unit for downloading data of a meteorological agency; and a lens unit fixed to the substrate, covering the light source unit, penetrating the light emitted from the light source unit, and made of a transparent material. The lens unit comprises: a lens unit body made of a transparent material; and a plurality of convex lens unit corresponding to the plurality of light source unit, respectively, and formed in the lens unit body. The sizes of front and rear areas of a light existing area formed by the light irradiated into the tunnel are different from each other.

Description

Tunnel type lighting device and lens unit for wall type lighting device {LIGHTING APPARATUS FOR MOUNTING ON WALL OF TUNNEL AND LENS UNIT THEREOF}

The present invention relates to a wall-mounted lighting device for a tunnel, and relates to a wall-mounted lighting device for a tunnel that can suppress glare of a driver of a vehicle operating in a tunnel.

Tunnels, such as highways, railroads, and underground roadways, are equipped with tunnel lighting devices to ensure driver visibility.

In general, a lighting device for a tunnel has a light distribution form that spreads widely from side to side along a road length and narrowly spreads along a road width, such as a bat-wing type.

1 is a view showing a conventional tunnel wall-mounted lighting device is installed.

Referring to FIG. 1, in the case of a general wall-mounted lighting device for a tunnel, a front area or a vehicle entrance direction area and a rear area or a vehicle entrance direction area of the light irradiation area AL by the lighting device 900 are formed to have the same size. do. And, the irradiation angle θ22 (with respect to the horizontal reference line H horizontal to the floor surface) and the irradiation angle (θ21) with respect to the rear area or the vehicle entrance direction area with respect to the front area or the vehicle entrance direction area of the lighting device 900 ) Is also formed to a size almost similar.

When the wall-mounted lighting device for the tunnel, such as the batwing type, is installed, the irradiation area is formed to be long in the front-rear direction of the driving direction of the vehicle 500, which has the advantage of helping to secure a visual field in a dark environment. When a vehicle enters a tunnel, as light is irradiated for a long time in the direction of the vehicle (the rear region of the light irradiation area AL), it may cause discomfort such as glare to the driver. In addition, when the driver is suddenly exposed to the light of the wall-mounted lighting device for the tunnel, there is a problem that a vehicle accident may occur due to glare.

Korean Patent Registration No. 10-1119125 (Invention name: How to form a tunnel lighting fixture and tunnel lighting fixture)

In order to solve the above problems, an embodiment of the present invention is to propose a wall-mounted lighting device for a tunnel and a lens unit thereof capable of suppressing glare of a driver.

A wall-mounted lighting device for a tunnel according to an aspect of an embodiment of the present invention includes: a wall-mounted lighting device for a tunnel installed in a tunnel, comprising: a substrate formed of a metal material; A plurality of light source units installed on the substrate; The substrate is mechanically mounted on a device to be tilted in a range between 10 ° and 20 °, and the substrate includes a plurality of SMD LED packages or a plurality of COB LED packages, and wires the LED package. Or a dimmer for wireless PWM control, a dimming control unit for controlling the dimmer, and an illuminance control device for each section in a tunnel including a communication unit for downloading weather station data, fixed to the substrate, and the light source unit. Covering, and transmitting a light emitted from the light source unit and includes a lens unit formed of a transparent material, the lens unit, the lens unit body formed of a transparent material, and a plurality of the light source unit respectively corresponding to the lens unit It is formed on the body and includes a plurality of convex lens parts, and is formed by light transmitted through the lens part and irradiated into the tunnel. Is the size of the size and the rear region of the front region of the light irradiation area is formed differently.

In addition, the lens unit is disposed above the light source unit corresponding to the lens unit, is formed convexly protruding in the opposite direction of the light source unit, the lens unit, toward the rear area with respect to the center line of the lens unit A first region and a second region facing the front region based on the center line of the lens unit, the average thickness of the first region is formed larger than the average thickness of the second region, protruding from the lens unit body It includes a raised portion formed between the lens portion, the thickness of the raised portion is formed to be raised to a higher height than the substrate, it may be formed to be raised to a lower height than the lens portion.

In addition, in the first region of the lens unit, a thickness reduction width of the first region from the first region to the first point, which is a first distance based on the center line, is obtained from the second region of the lens portion, As a reference, the first area from the first point to the third point spaced apart by a third distance from the first point is less than the thickness reduction width of the second area to the second point, which is the second distance of the same size as the first distance. The thickness reduction width of is greater than the thickness reduction width of the second region from the second point to a fourth point spaced apart by a fourth distance equal to the third distance, wherein the first distance and the second distance are the third distance And it is formed larger than the fourth distance, the thickness of the first region and the second region at the border of the first region and the second region may be formed to be the same as each other.

In addition, an irradiation angle of light passing through the first region based on a vertical reference line perpendicular to the bottom surface may be formed smaller than an irradiation angle of light passing through the second region.

Further, on the lower surface of the lens unit, an accommodating groove recessed toward the first region and the second region of the lens portion is formed so that the light source unit is accommodated, and the inner surface of the accommodating groove is formed to be rounded. You can.

Further, the size of the front area of the light irradiation area formed by the light transmitted through the lens unit and irradiated into the tunnel is formed to be larger than the size of the rear area of the light irradiation area, and a vehicle passes through the tunnel. The direction may be formed parallel to the direction from the rear area toward the front area.

In addition, the amount of light in the front region of the light irradiation region may be larger than the amount of light in the rear region of the light irradiation region.

In addition, the irradiation angle of the boundary surface of the front area of the light irradiation area based on the vertical reference line perpendicular to the bottom surface may be formed to be larger than the irradiation angle of the boundary surface of the rear area.

A lens unit installed in a wall-mounted lighting device for a tunnel according to another aspect of the present invention includes a lens unit body formed of a transparent material, a plurality of convex shapes corresponding to a plurality of the light source units, respectively formed on the lens unit body It includes a lens portion, and the lens portion is formed to protrude convexly in the opposite direction of the light source unit, the lens portion, the first region facing the rear region with respect to the center portion of the lens portion and the center portion of the lens portion It includes a second region facing the front region, and an average thickness of the first region is formed larger than an average thickness of the second region.

In addition, the lens unit is disposed above the light source unit corresponding to the lens unit, is formed convexly protruding in the opposite direction of the light source unit, the lens unit, toward the rear area with respect to the center line of the lens unit A first region and a second region facing the front region based on the center line of the lens unit, the average thickness of the first region is formed larger than the average thickness of the second region, the first region of the lens unit In the thickness reduction width of the first region to a first point that is a first distance based on the center line of the lens portion, in the second region of the lens portion, the same size as the first distance based on the center line of the lens portion The first zero from the first point to a third point spaced apart by a third distance from the first point is less than the thickness reduction width of the second area to the second point, the second distance of The thickness reduction width of the inverse is greater than the thickness reduction width of the second region from the second point to the fourth point spaced apart by a fourth distance equal to the third distance, wherein the first distance and the second distance are the third It is formed larger than the distance and the fourth distance, the thickness of the first region and the second region at the border of the first region and the second region are the same as each other, and the lens portions protruding from the lens unit body It includes a raised portion formed between, the thickness of the raised portion is formed to be raised to a higher height than the substrate, it may be formed to be raised to a lower height than the lens portion.

According to the proposed embodiment, it is possible to suppress the glare of the driver and secure a wide field of view inside the tunnel.

1 is a view showing a conventional tunnel wall-mounted lighting device is installed.
2 is a view showing a tunnel wall-mounted lighting device is installed according to an embodiment of the present invention.
3 and 4 are views showing a lens unit of the wall-mounted lighting device of FIG. 1.
5 is a view showing a cross-section of the wall-mounted lighting device for the tunnel of FIG. 1.
FIG. 6 is a view showing an irradiation area by light emitted from the wall-mounted lighting device for tunnel of FIG. 1.
7 is a view of a wall-mounted lighting device for a tunnel proposed in the present invention.

Advantages and features of the present invention, and methods for achieving them will be clarified with reference to embodiments described below in detail together with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but will be implemented in various different forms, and only the present embodiments allow the disclosure of the present invention to be complete, and common knowledge in the art to which the present invention pertains. It is provided to completely inform the person having the scope of the invention, and the present invention is only defined by the scope of the claims.

Although the first, second, etc. are used to describe various components, it goes without saying that these components are not limited by these terms. These terms are only used to distinguish one component from another component. Therefore, it goes without saying that the first component mentioned below may be the second component within the technical spirit of the present invention.

The same reference numerals refer to the same components throughout the specification.

Each of the features of the various embodiments of the present invention may be partially or totally combined with or combined with each other, and technically various interlocking and driving may be possible as those skilled in the art can fully understand, and each of the embodiments may be independently implemented with respect to each other. It can also be implemented together in an association relationship.

On the other hand, potential effects that can be expected by the technical features of the present invention, which are not specifically mentioned in the specification of the present invention, are treated as described in the present specification, and this embodiment is applied to those skilled in the art. Since the present invention is provided to more fully describe the contents shown in the drawings, it may be exaggeratedly expressed as compared to the actual implementation of the invention, and a detailed description of a configuration determined to unnecessarily obscure the subject matter of the present invention Omitted or briefly described.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

2 is a view showing a tunnel wall-mounted lighting device is installed according to an embodiment of the present invention.

Referring to FIG. 2, the wall-mounted lighting device 1 for a tunnel according to an embodiment of the present invention is installed inside the tunnel T, and in the process of driving the vehicle 500 inside the tunnel T It provides light to secure the driver's view.

The light irradiation area AL formed by the light emitted from the wall-mounted lighting device 1 for the tunnel includes the rear area AL1 and the front area AL2, and the rear area AL1 and the front area AL2 Are formed differently. The traveling direction of the vehicle 500 is formed in a direction from the rear area AL1 toward the front area AL2, and preferably, the size of the front area AL2 is larger than the size of the rear area AL1. In addition, the irradiation angle θ12 of the boundary surface BL2 of the front area AL2 of the light irradiation area AL with respect to the horizontal reference line H horizontal with respect to the bottom surface is the rear of the light irradiation area AL It is formed larger than the irradiation angle θ11 of the boundary surface BL1 of the region AL1. That is, one illumination device 1 irradiates light to the front area AL2 for a long time, and irradiates light relatively shortly to the rear area AL1.

The rear area AL1 facing the direction in which the vehicle 500 enters is formed to have a relatively small irradiation angle θ11, so that the size of directly irradiating light to the driver's eyes of the vehicle 500 is reduced. In addition, the front area AL2, which is formed to be long in the direction in which the vehicle 500 travels, allows light to be irradiated over a wide range irrespective of the vehicle driver's field of view, so that the driver's field of view can be secured in a dark environment. .

Hereinafter, the configuration of the wall-mounted lighting device 1 for a tunnel according to this embodiment will be described in detail.

3 and 4 are views showing a lens part of the tunnel lighting apparatus of FIG. 1, and FIG. 5 is a view showing a cross section of the tunnel lighting apparatus of FIG. 1.

3 to 5, the wall-mounted lighting device 1 for a tunnel according to the present embodiment includes a substrate 300 formed of a metal material and a plurality of light source units 200 installed on the substrate 300 ), Fixed to the substrate 300, covers the light source unit 200, and transmits light emitted from the light source unit 200, and includes a lens unit 100 formed of a transparent material.

The substrate 300 may be, for example, a PCB substrate formed of a metal material such as metal or aluminum, and rapidly generate heat generated from the plurality of light source units 200 installed on the substrate 300 for the tunnel wall type. It can diverge to the outside of the lighting device (1).

The light source unit 200 includes a light emitting surface 210 that emits light, and may be, for example, an LED (Light Emitting Diode) module. In this embodiment, the light source unit 200 may be described as an exemplary LED, but an incandescent lamp, a halogen lamp, a fluorescent lamp, and an organic light emitting diode (OLED). It can be formed of various light sources for emitting light.

The lens unit 100 is a lens unit body 110 formed of a plate-shaped transparent material, and corresponding to each of a plurality of light source units 200 and formed on the lens unit body 110 and having a plurality of convex lens units ( 120), and a raised portion 130 formed between the lens portion 120.

The lens unit body 110 is formed of a transparent material, and for example, may be formed of polycarbonate. In this embodiment, the lens unit body 110 is exemplarily described as a structure formed of polycarbonate, but may be formed of a material having various transparency such as glass and polypropylene.

A plurality of through-holes 111 through which a fastening member for connecting to the substrate 300 is penetrated may be formed on the lens unit body 110 along the rim of the lens unit body 110.

The lens unit 120 is disposed above the light source unit 200 corresponding to the lens unit 120, and is convexly formed from the lens unit body 110 in the opposite direction of the light source unit 200.

The lens unit 120 is based on the first region 121 facing the rear region AL1 of the light irradiation area AL with respect to the center line C of the lens unit 120 and the center line C of the lens unit In addition, the second region 122 facing the front region AL2 is included. The average thickness of the first region 121 is larger than the average thickness of the second region 122. That is, the first region 121 is formed to be thicker than the second region 122 so that light passing through the first region 121 is formed to have more straightness than light passing through the second region 122.

In more detail, the first region 121 from the first region 121 of the lens unit 120 to the first point P1 which is the first distance d1 based on the center line C of the lens unit 120 The thickness reduction width of) is the second distance d2 having the same size as the first distance d1 based on the center line C of the lens unit 120 in the second region 122 of the lens unit 120. It is formed smaller than the thickness reduction width of the second region 122 up to the second point P2.

Further, the thickness reduction width of the first region 122 from the first point P1 to the third point P3 spaced apart by the third distance d3 is the third distance d3 from the second point P2. It is formed larger than the thickness reduction width of the second region 122 up to the fourth point P4 spaced apart by a fourth distance d4 equal to.

That is, the thickness of the first region 121 of the lens unit 120 is reduced to a level less than the thickness of the second region 122 in the lateral direction of the first region 121 from the center line C, After a certain point (the fourth point P4), it is reduced to a larger reduction width than the thickness reduction width of the second region 122. The thickness of the edge portion of the first region 121 is formed to be substantially the same as the thickness of the edge portion of the second region 122.

The first distance d1 and the second distance d2 are formed to be larger than the third distance d3 and the fourth distance d4. That is, the size in which the size in which the thickness of the first region 121 is reduced is the size of the section in which the size in which the thickness of the second region 121 is reduced is small, and the size in which the thickness in which the thickness of the first region 121 is reduced is the second region. Since the thickness of the 121 is larger than the size of the section that is larger than the reduced size, the average thickness of the first region 121 is larger than the average thickness of the second region 122.

On the other hand, the receiving groove is recessed toward the first region 121 and the second region 122 of the lens unit 120 so that one light source unit 200 can be accommodated on the lower surface of the lens unit 120. 125 is formed, the inner surface of the receiving groove 125 may be formed to be round. The inner surface of the receiving groove 125 may be formed in a symmetric shape with respect to the center line (C).

The raised portion 130 is formed between the lens portions 120 protruding from the lens unit body 110 and is formed by being raised to a lower height than the lens portion 120. The raised portion 130 may disperse the stress or other external force caused by heat applied to the lens portion 120 protruding from the lens unit body 110 to suppress the lens portion 120 from being damaged. A portion of the lens unit body 110 is overlapped with each other on the rim of the raised portion 130. At this time, the raised portion 130 is formed to be raised to a higher height than the substrate 300, it may be raised to a lower height than the lens portion 120.

In the lighting device 1 for a tunnel according to the present embodiment, the irradiation angle θ11 of the light L1 passing through the first region 121 based on the vertical reference line v perpendicular to the bottom surface is It is formed smaller than the irradiation angle (θ12) of the light passing through the second region 122. That is, the thickness of the first region 121 is relatively thick compared to the second region 122 and the second of the light L1 passing through the first region 121 as the transmission surface is relatively flat. It has relatively more vertical components than the light L2 transmitted through the region 122. The light L1 passing through the first region 121 is irradiated toward the rear region AL1 of the light irradiation region AL, and the light L2 passing through the second region 122 is the light irradiation region AL Is irradiated toward the front region AL2.

FIG. 6 is a view showing an irradiation area by light emitted from the tunnel lighting device of FIG. 1.

Referring to FIG. 6, the light irradiation area AL of the tunnel lighting device 1 according to the present embodiment includes a rear area AL1, a front area AL2, and an intermediate area AL3.

As described above, the size of the front area AL2 is formed larger than the rear area AL1, thereby suppressing glare of the driver and securing a wide field of view inside the tunnel. And, the amount of light in the front region AL2 is formed larger than the amount of light in the rear region AL1. The intermediate region AL3 is formed between the front region AL2 and the rear region AL1, that is, the vertical direction in the lighting device 1, and the amount of light in the middle region AL3 is the front region AL2 and the rear region. It is formed smaller than (AL1).

Referring to FIG. 7, the substrate formed of a metal material is mechanically tilted in a range between 10 ° and 20 °, so that the size of the front area and the back area of the light irradiation area are different even by a mechanical method. Is formed.

In addition, the plurality of light source units installed on the substrate is composed of a plurality of SMD (Surface Mounted Device) LED package or a plurality of COB (Chip on Board) LED package, the LED package is illuminated by wire or wireless PWM control method In addition to the different illuminance at the tunnel entrance, in the middle of the tunnel, and at the exit of the tunnel by connecting with a dimmer that can adjust the temperature, the weather station data such as external weather or seasonal sunrise and sunset times are downloaded in real time or when entering the tunnel or When entering the tunnel exit, the illuminance is investigated differently to minimize the driver's dark adaptation time.

According to the wall-mounted lighting device for a tunnel according to the proposed embodiment, it is possible to suppress glare of the driver and secure a wide field of view inside the tunnel.

Although the preferred embodiments of the present invention have been described above, the present invention is not limited thereto, and it is possible to carry out various modifications within the scope of the claims and detailed description of the invention and the accompanying drawings. It is natural to fall within the scope of.

Claims (10)

In the wall-mounted lighting device for a tunnel installed in the tunnel,
A substrate formed of a metal material;
A plurality of light source units installed on the substrate;
The substrate is mechanically mounted on a mechanism to be tilted in a range between 10 ° and 20 °,
The substrate includes a plurality of SMD LED packages or a plurality of COB LED packages,
Includes a dimmer for wire or wireless PWM control of the LED package,
It includes a control unit for controlling the dimmer and a light control unit for each section in the tunnel including a communication unit for downloading the meteorological agency data,
It is fixed to the substrate, and covers the light source unit, and includes a lens unit formed of a transparent material while transmitting light emitted from the light source unit,
The lens unit includes a lens unit body formed of a transparent material, a plurality of lens units each corresponding to a plurality of the light source units, and formed on the lens unit body and having a convex shape,
The size of the front region and the size of the rear region of the light irradiation region formed by the light transmitted through the lens portion and irradiated into the tunnel is formed differently,
The lens unit is disposed above the light source unit corresponding to the lens unit, and is convexly formed in the opposite direction of the light source unit,
The lens unit includes a first area toward the rear area based on the center line of the lens unit and a second area toward the front area based on the center line of the lens unit, and an average thickness of the first area is the second area. Is formed larger than the average thickness of the region,
And a raised portion formed between the lens portions protruding from the lens unit body,
The thickness of the raised portion is formed to be raised to a higher height than the substrate, the wall-mounted lighting device for a tunnel, characterized in that formed to be raised to a lower height than the lens portion.
delete According to claim 1,
In the first region of the lens unit, a thickness reduction width of the first region from the first region to a first point based on the center line of the lens unit is based on the center line of the lens unit in the second region of the lens unit. Less than the thickness reduction width of the second region up to the second point which is the second distance having the same size as the first distance,
The thickness reduction width of the first region from the first point to the third point spaced apart by the third distance is the second from the second point to the fourth point spaced apart by the fourth distance equal to the third distance. Greater than the thickness reduction width of the area,
The first distance and the second distance are formed larger than the third distance and the fourth distance, and the thicknesses of the first area and the second area at the borders of the first area and the second area are equal to each other. A wall-mounted lighting device for a tunnel, characterized in that.
According to claim 1,
A wall-mounted lighting device for a tunnel, characterized in that an irradiation angle of light passing through the first area is smaller than an irradiation angle of light passing through the second area based on a vertical reference line perpendicular to the bottom surface.
According to claim 1,
On the lower surface of the lens unit, an accommodation groove is formed recessed toward the first region and the second region of the lens unit so that the light source unit can be accommodated, and the inner surface of the accommodation groove is formed to be rounded. A wall-mounted lighting device for tunnels.
According to claim 1,
The size of the front region of the light irradiation region formed by the light transmitted through the lens portion and irradiated into the tunnel is formed larger than the size of the rear region of the light irradiation region,
A wall-mounted lighting device for a tunnel, characterized in that the direction in which the vehicle passes in the tunnel is parallel to the direction from the rear area toward the front area.
The method of claim 6,
A wall-mounted lighting device for a tunnel, characterized in that the amount of light in the front region of the light irradiation region is larger than the amount of light in the rear region of the light irradiation region.
The method of claim 6,
A wall-mounted lighting device for a tunnel, characterized in that the irradiation angle of the boundary surface of the front area of the light irradiation area is greater than that of the boundary area of the rear area based on a vertical reference line perpendicular to the bottom surface.
In the lens unit installed in the wall-mounted lighting device for a tunnel,
A lens unit body formed of a transparent material, and a plurality of light source units, each corresponding to the lens unit body, and including a plurality of convex lens parts,
The lens unit is formed to protrude convexly in the opposite direction of the light source unit,
The lens unit includes a first region facing the rear region based on the center line of the lens portion and a second region facing the front region based on the center line of the lens portion, and an average thickness of the first region is the second region. It is formed larger than the average thickness,
Further comprising a raised portion formed between the lens portion protruding from the lens unit body,
The thickness of the raised portion is formed to be raised to a higher height than the substrate on which the light source units are installed, and the lens unit of the wall-mounted lighting device for tunnels, characterized in that formed to be raised to a lower height than the lens portion.
The method of claim 9
The lens unit is disposed above the light source unit corresponding to the lens unit, and is convexly formed in the opposite direction of the light source unit,
The lens unit includes a first region facing the rear region based on the center line of the lens portion and a second region facing the front region based on the center line of the lens portion, and an average thickness of the first region is the second region. Is formed larger than the average thickness of the region,
In the first region of the lens unit, a thickness reduction width of the first region from the first region to a first point based on the center line of the lens unit is based on the center line of the lens unit in the second region of the lens unit. Less than the thickness reduction width of the second region up to the second point which is the second distance having the same size as the first distance,
The thickness reduction width of the first region from the first point to the third point spaced apart by the third distance is the second from the second point to the fourth point spaced apart by the fourth distance equal to the third distance. Greater than the thickness reduction width of the area,
The first distance and the second distance are formed larger than the third distance and the fourth distance, and the thicknesses of the first area and the second area at the borders of the first area and the second area are equal to each other. Lens unit for wall-mounted lighting for tunnels.

Images